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Recent Advances in Science and Technology Education, Ranging from Modern Pedagogies to Neuroeducation and Assessment
Recent Advances in Science and Technology Education, Ranging from Modern Pedagogies to Neuroeducation and Assessment
Edited by
Zacharoula Smyrnaiou, Martin Riopel and Menelaos Sotiriou
Recent Advances in Science and Technology Education, Ranging from Modern Pedagogies to Neuroeducation and Assessment Edited by Zacharoula Smyrnaiou, Martin Riopel and Menelaos Sotiriou This book first published 2016 Cambridge Scholars Publishing Lady Stephenson Library, Newcastle upon Tyne, NE6 2PA, UK British Library Cataloguing in Publication Data A catalogue record for this book is available from the British Library Copyright © 2016 by Zacharoula Smyrnaiou, Martin Riopel, Menelaos Sotiriou and contributors All rights for this book reserved. No part of this book may be reproduced, stored in a retrieval system, or transmitted, in any form or by any means, electronic, mechanical, photocopying, recording or otherwise, without the prior permission of the copyright owner. ISBN (10): 1-4438-7125-7 ISBN (13): 978-1-4438-7125-9
TABLE OF CONTENTS
Organizers and Supporters.......................................................................... ix Committees .................................................................................................. x Preface ...................................................................................................... xiii Part 1: Modern Pedagogies in Science and Technology Education Reflexive Return and Quality of the Language using Information and Communication Technologies .............................................................. 2 Michel Pronovost and Katerine Deslauriers Community of Practice and its Applied Results in the Teaching of Science-Technology of the Secondary Sector (High School) ............... 15 Diane Gauthier and Ugo Collard-Fortin Teaching of the Renewable Energy Sources to Secondary School Students with Science Activities based on Socio-Scientific Argumentation............ 30 Gülsüm Yasemin ùahintürk and Mehtap Yurdatapan Concept Mapping as Cognitive Tool in Science Education: An Analysis of Students’ Learning using SOLO Taxonomy .................... 43 Vasiliki Bakouli and Athanassios Jimoyiannis Refining a Revised Bloom's Taxonomy to Enhance Student Learning in Computer Science Courses .................................................................... 59 Sofia Tzelepi and Isabella Kotini Education of Roma Children: Developing Intercultural Understanding and Training Skills for Teachers through Distance Learning and a Constructivist Teaching Model ........................................................ 71 Christos Parthenis
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Part 2: New Technologies in Science and Technology Education Teaching the Phases of the Moon and the Seasons in a Digital Planetarium ................................................................................................ 86 Pierre Chastenay The KITLoK: A Dynamic Interaction Analysis Model for Instrumented Learning Situations ................................................ 98 Rodica Ailincai and François-Xavier Bernard Designing and Implementing Experimental Microcomputer-Based Activities by Primary Student Teachers .................................................. 116 Dimitris Stavrou and Vasilis Savvorginakis Education of Roma Children: The Importance of Supporting Networking of Schools and All Participants through Web Applications and Social Media ................................................................ 125 Christos Parthenis, Eirini Tseliou and Aikaterini Tsoka Recognizing Interesting Points in Constructionist Activities Using Artificial Intelligence............................................................................... 136 Marios Xenos, Chronis Kynigos and Maria Daskolia Multi-Agent Models, Made in NetLogo, for Teaching Simple Properties of Complex Natural Systems, and their Instructional Use ....................... 146 Aristotelis Gkiolmas, Maria Papaconstantinou, Anthimos Chalkidis and Constantine Skordoulis Developing Historical Significance using Digital Technology: An Example of Greek Ancient History ................................................... 158 Elias Stouraitis Study of the Problem “Exploration vs. Exploitation” in the Context of an Ecosystem with the “Multi-Agent” Software NetLogo .................. 167 Georgios Gkaras, Panayiotis Costaridis, Dimitris Yiatas Part 3: Assessment in Science and Technology Education Assessing Students’ Knowledge on Refraction ....................................... 180 Claudia Haagen and Sebastian Glantschnig
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Tracing Computer Assisted Assessment for learning Capability in Greek Teachers .................................................................................... 197 Zacharoula Smyrnaiou, Evangelia Petropoulou, Eleni Spinou and Kathrin Otrel Cass Part 4: Teaching and Learning in the Light of Inquiry Learning Methods Establishing a Common Pattern for Educational Tools’ Design Process: The Inquiry-based Development Approach of a Tool Addressing Science Related Issues ............................................................................. 220 Zacharoula Smyrnaiou, Evangelia Petropoulou, Maria Margoudi and Ioannis Kostikas Responsible Research and Innovation in Science Education: The IRRESISTIBLE Project ................................................................... 239 Dimitris Stavrou Development of Argumentation Skills through a Web-based Learning Environment Devoted to ‘Antimicrobial Resistance’ .............................. 243 Argyro Scholinaki, Constantinos P. Constantinou, Elena Siakidou and Dimitris Koursaris Part 5: Neuroscience and Science Education Intuitive Interference in Science and Mathematics Education................. 266 Ruth Stavy and Reuven Babai A Study of Affect and Cognition in Tutor-supported Collaborative Learning in Physics ................................................................................. 276 Julien Mercier, Patrick Charland, Dave Saint-Amour, Line Laplante, Martin Riopel, Steve Masson and Vivek Venkatesh Integrating the Perspective of Neuroscience in Tutoring Research in Physics: Why And How?..................................................................... 287 Julien Mercier
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Part 6: Conceptual Understanding and Conceptual Change in Science and Technology Education Causality of Magnetism: Development of a Video-based Intervention for Primary Students ................................................................................ 298 Vasiliki Spiliotopoulou and Christina Lianeri Is Touch Sensory Input Necessary for Science Learning through Experimentation among Young Learners? ................................. 310 Zacharias C. Zacharia Engineering Students’ Teaching Plans on Periodicity: Transforming School Texts ..................................................................... 321 Vasiliki Spiliotopoulou and Chrissavgi Triantafillou Part 7: Interest, Attitude and Motivation in Science and Technology Education Teachers’ and Learners’ Perceptions of the Mathematics, Science and Technology Curricula in Austria and Cyprus ................................... 334 Veronika Rechberger, Michalis Livitziis, Judith Aldrian, Maria Hadjidemetri, Constantinos P. Constantinou and Leopold Mathelitsch A Review on Girls and their Interest for Science and Technology: Which Questions do Researchers Ask and How do They Answer Them?.......... 346 Marie-Hélène Bruyère, Patrice Potvin and Abdelkrim Hasni The Effect of Technological Design Processes (TDP)-based Activities on Students’ Interest in Science and Technology Classes ....................... 363 Nancy Brouillette, Patrice Potvin, Ghislain Samson and Abdelkrim Hasni
ORGANIIZERS AN ND SUPPO ORTERS
Organizerrs:
Co-Organ nizers:
Supportin ng Partnerss: Postgraduate Programme " "Theory, Practtice and Evaluatio on of the Educcational Processs" National and Kapodistrian K Unniversity of Ath hens (NKUA) ty of Philosophy y, School of Phillosophy, Faculty Education and d Psychology, D Department of Education E
COMMITTEES
e-Learning Center of Continuing Education and Training National and Kapodistrian University of Athens (NKUA) HERODOTOS Publishing House
The Conference is under the Auspices of:
Scientific Program Committee: Ailincai Rodica Alimisis Dimitris Baron Georges-Louis Bernard François-Xavier Blanquet Estelle Blaya Catherine Bogner Franz X. Charland Patrick Chastenay Pierre
(University of French Polynesia, Tahiti, French Polynesia) (School of Pedagogical & Technological Education, Greece) (Université Paris Descartes, France) (Université Paris Descartes, France) (Université de Nice, France & Université de Genève, Switzerland) (Université de Nice Sophia Antipolis, France) (University of Bayreuth, Germany) (Université du Québec à Montréal, Canada) (Université du Québec à Montréal, Canada)
Recent Advances in Science and Technology Education Chen Junjun Constantinou Constantinos Daskolia Maria De-groot Reuma Depover Christian Dimitriou Anastasia Galani Lia Gatt Suzanne Grigoriadou Maria Hatzikraniotis Euripides Hench Thomas Jimoyiannis Athanassios Kalogiannakis Michail Koliopoulos Dimitris Komis Vassilis Kordaki Maria Kynigos Chronis Kyza Eleni Mercier Julien Mikropoulos Tassos A. Moore Emily Orange Denise Otrel-Cass Kathrin Papageorgiou George Papanikolaou Kyparisia Pavlatou Evangelia Pedaste Margus Plakitsi Katerina Potvin Patrice Pronovost Michel Psaromiligkos Yannis P. Psycharis Giorgos Psycharis Sarantos Raes Annelies Ravanis Kostas Renken Maggie D. Retalis Symeon
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(The Hong Kong Institute of Education, Hong Kong) (University of Cyprus, Cyprus) (National and Kapodistrian University of Athens, Greece) (Hebrew University of Jerusalem, Israel) (Université de Mons, Belgium) (Democritus University of Thrace, Greece) (National and Kapodistrian University of Athens, Greece) (University of Malta, Malta) (National and Kapodistrian University of Athens, Greece) (Aristotle University of Thessaloniki, Greece) (Delaware County Community College, USA) (University of Peloponnese, Greece) (University of Crete, Greece) (University of Patras, Greece) (University of Patras, Greece) (University of the Aegean, Greece) (National and Kapodistrian University of Athens, Greece) (Cyprus University of Technology Cyprus) (Université du Québec à Montréal, Canada) (University of Ioannina, Greece) (University of Colorado, USA) (Université de Lille 3, France) (Aalborg Universitet, Denmark) (Democritus University of Thrace, Greece) (School of Pedagogical & Technological Education, Greece) (National Technical University of Athens, Greece) (University of Tartu, Estonia) (University of Ioannina, Greece) (Université du Québec à Montréal, Canada) (Collège Jean-de-Brébeuf, Québec, Canada) (Technological Education Institute of Piraeus, Greece) (National and Kapodistrian University of Athens, Greece) (School of Pedagogical & Technological Education, Greece) (Ghent University, Belgium) (University of Patras, Greece) (Georgia State University, USA) (University of Piraeus, Greece)
xii Riopel Martin Sampson Demetrios G. Sgouropoulou Cleo Smyrnaiou Zacharoula Sotiriou Menelaos Sotiriou Sofoklis Spiliotopoulou Vasiliki Spyrtou Anna Stamovlasis Dimitris Stavrou Dimitris Teodoro Vitor Duarte Vavougios Denis Villeneuve Stéphane Weil-Barais Annick Whitelock Denise Xalkia Krystallia Zacharia Zacharias
Committees (Université du Québec à Montréal, Canada) (University of Piraeus, Greece) (Technological Educational Institute of Athens, Greece) (National and Kapodistrian University of Athens, Greece) (Science View, Greece) (Ellinogermaniki Agogi, Greece) (School of Pedagogical & Technological Education, Greece) (University of Western Macedonia, Greece) (Aristotle University of Thessaloniki, Greece) (University of Crete, Greece) (Universidade Nova de Lisboa, Portugal) (University of Thessaly, Greece) (Université du Québec à Montréal, Canada) (Laboratoire de Psychologie des Pays de Loire, France) (The Open University Walton Hall, United Kingdom) (National and Kapodistrian University of Athens, Greece) (University of Cyprus, Cyprus)
Local Organizing Committee: Smyrnaiou Zacharoula Kostikas Ioannis Margoudi Maria Petropoulou Evangelia Spinou Eleni Kynigos Chronis Daskolia Maria Latsi Maria Makri Katerina Moustaki Foteini Psycharis Giorgos Xenos Marios Yiannoutsou Nikoleta
(ETL, NKUA, Greece) (Faculty of Physics, NKUA, Greece) (Faculty of PPP, NKUA, Greece) (Faculty of PPP, NKUA, Greece) (Faculty of PPP, NKUA, Greece) (ETL, NKUA, Greece) (EEL, NKUA, Greece) (ETL, NKUA, Greece) (ETL, NKUA, Greece) (ETL, NKUA, Greece) (ETL, NKUA, Greece) (ETL, NKUA, Greece) (ETL, NKUA, Greece)
PREFACE
Dear Colleagues, This book you hold in your hands is a publication composed by the majority of the papers from the First International Conference on “New Developments in Science and Technology Education” NDSTE2014 (http://ndste2014.weebly.com/), that was held in Corfu Island, in Greece, from Thursday, May 29th, to Saturday, May 31st, 2014, The conference was organized by the Educational Technology Lab (ETL) of the National and Kapodistrian University of Athens (NKUA) and Équipe de Recherche en Éducation Scientifique et Technologique (EREST) de l’Université du Québec à Montréal (UQÀM) in collaboration with the non-profit organization Science View, under the auspices of the Ministry of Education of Greece. It was structured around seven main thematic axes as follow: x x x x x x
Modern Pedagogies in Science and Technology Education, New Technologies in Science and Technology Education, Assessment in Science and Technology Education, Teaching and Learning in the light of Inquiry learning Methods, Neuroscience and Science Education, Conceptual Understanding and Conceptual Change in Science and Technology Education, x Interest, Attitude and Motivation in Science and Technology Education Science and technology education research not only concentrates on the teaching of science concepts and addressing misconceptions that learners may hold, but also as they co-evolve they examine and integrate into their epistemologies innovative approaches such as Inquiry-Based Science Learning that situates learning in authentic science practices. New developments in science and technology education rely on a wide variety of methods, borrowed from many other sciences such as computer science, cognitive science, sociology and neurosciences. A lot of studies indicate that students who use new technologies, enlightened by new developments in science education, not only get better
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grades on exams, but also demonstrate better understanding. Constructing and using scientific conceptual models are also necessary in order to reach high levels of scientific literacy. Therefore, it is important for science courses to be designed in ways that support and help students understand the pivotal role of models in scientific episteme and of modeling in scientific inquiry. Research consistently indicates that information and communications technology (ICT) has the potential to support education for knowledge age skills in two distinct but compatible ways. The first is through Exploratory Learning Environments including games and simulations, which hold the promise of making abstract ideas concrete and manipulable. In the last 10 years a relatively small number of breakthrough digital artifacts has been produced for students to use expressive and exploratory tools that assist in developing the learning of scientific and technological ideas. At the same time, they have illustrated ways for students to adopt an enquiry scientific stance to these subjects striving for rigor, insight and the ability to abstract and generalize. A second way in which ICT can transform learning is through computer supported learning dialogues as part of the Computer Supported Collaborative Learning CSCL. Computer supported collaborative tools have provided users with the means to engage in argumentation and the possibility to acquire skills in collectives in ways not possible before. The key factor in shaping the quality of science education and technology is assessment. During the last decade within the context of educational reforms carried out in various countries around the world there has been a tendency to focus on the outcomes from assessment practices. So far, assessment has been often accumulative and generally conceived as an end to itself and it is regarded to be the responsibility of the teacher to adequately prepare students, apply assessment strategies and produce reliable and valid information from assessment. The adoption of new pedagogical theories has triggered a change of focus from assessment that focuses solely on the acquisition of knowledge/learning (assessment of learning) to assessment of the effective implementation of skills in various environments (assessment for learning), thus putting emphasis on the cognitive procedure rather than the outcome. Science and technology education research, influenced by inquirybased learning, not only concentrates on the teaching of science concepts and addressing misconceptions that learners may hold, but also emphasizes how students learn and tries to find out ways to achieve better learning. Inquiry-based learning is a widespread learning method being embraced by many national educational systems all over the world. It is a highly-structured and thoughtfully designed-endeavour with the potential
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to increase engagement in knowledge inference processes and foster deep access to cognitive aspects through the development of a hands-on, research-based procedural task. It sets an instructional frame that bridges the gap between the learning process and authentic scientific practices. As an instructional process it extends and promotes the learning of students in a way that addresses their interests while at the same time it facilitates a visible representation of their thinking and learning. Intuitive Science and Conceptual Change are very important in science and technology education. Several explanations to students' representations (or misconceptions, etc.) were given in the last decades by researchers in science education. Students encounter difficulties in solving a wide range of problems in science education. Some of these difficulties may stem from intuitive interference of a salient (automatically/intuitively processed) irrelevant variable with the formal/logical reasoning that is needed for the handling of that is needed for the handling of the relevant variable. This interference is reflected in students’ erroneous responses to numerous tasks in science education. New developments in this field are related to the neuroeducation or to the neuroscience techniques. Another important aspect is motivation. Many researches focus on how to motivate students, boys and girls in science and technology and inspire them to follow scientific careers. Specifically, during the last decade, Europe and Canada have turned their attention to attracting young people in science education and consequently in scientific careers. Despite targeted strategies and policies that have been established for this purpose and the significant importance of science for society, there continues to appear reduced interest on the part of young people to follow this career path, setting, thus, an increasing gap between the social demand and the scientific expertise. Studying the factors that affect interest and attitude and determine the choice about their professional future, the results show that gender and discipline continue to remain key factors in shaping young people’s stance as had previously emerged from the results of the Project “Rose” and other projects. The organizers, Zacharoula Smyrnaiou Martin Riopel Menelaos Sotiriou
PART 1: MODERN PEDAGOGIES IN SCIENCE AND TECHNOLOGY EDUCATION
REFLEXIVE RETURN AND QUALITY OF THE LANGUAGE USING INFORMATION AND COMMUNICATION TECHNOLOGIES MICHEL PRONOVOST AND KATERINE DESLAURIERS
Abstract. The quality of the French language is a priority for all colleges in Quebec. It has been highly studied, but this is the first time that science and non-science students have been compared regarding their quality of language. This study measures the effects of revision (auto correction and rewriting) of texts written by science students and non-science students on the perception of their capacity to improve at the language level by using information and communication technologies. During the session, students had to write three texts (the first one by hand and the others with a computer). Teachers corrected the writings by indicating the mistakes. Students then had to rework their texts using different tools, including technological tools, and hand them back to their teachers who recorrected them. The sample (n=148) was mainly composed of girls (64.9 %). It was composed of students who were registered in a pre-university program (46.9 % in science) that mainly speak French at home (73 %). The majority of the students have access to language correction software at the home (56.8 %). Science students consider themselves less competent in using Antidote than those who are not in the sciences (t=5,594, p =, 000). They thus use it less for the revision of their school work (t=4.643, p =.000). Science students consider the comments of their professors more useful than the other students (t=2.02, p=.044). They understand them better (t=2.15, p=.032) and feel more capable of satisfying the requirements of their professors (t=2.25, p=.025). Science students make more mistakes in spelling (t=3.10, p=.002), grammar (t=3.30, p=.001), punctuation (t=2.92, p=.004), syntax (t=7.20, p=.000), grammar of the text (t=4.13, p=.000), vocabulary (t=1.86, p=.064) and specific vocabulary mistakes (t=5.90, p=.000) than those who are not in science. Although they had better marks in high school (t=5.38, p=.000) and a better R score in college, students in science had no significant difference
Michel Pronovost and Katerine Deslauriers
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in French marks at high school than the others. At home, students use virtual tools more than paper ones, even though they have access to them. At the end of the session, the reflexive return on their works and the fact of having been able to rework their texts brought them an overall vision of the quality of their written French. Reflexive return allowed the students to identify the strengths and the gaps that are specific errors in French, the general quality of the contents of the text, and the precision and depth of their ideas. We can conclude that when we give them the time and the opportunity to review their texts, they get satisfaction from it and some pleasure. Keywords. Antidote, Correction, ICT, Quality of the language, Reflexive Return, Word
1. Introduction The quality of the French language is a priority for all colleges in Quebec. Several strategies were put in place for the improvement of the quality of the French language; however, recorrection has not been studied in depth. We believe that it is a promising way to improve the quality of the French language.
2. Theoretical Framework Several research papers have had the study of the reading and writing skills of collegians as a subject; others have analysed the effects of the educational interventions of professors in the mastering of French [1, 2, 3, 4, 5], but few have concentrated on the metacognitive capacity of autoreflection and autocorrection.
Correction The time and energy that is dedicated by professors to the correction and annotation of work has sense only if students take these remarks into account [6] and if corrections are made in a terminal mode and circumstantiated [7]. Formative assessment, partial correction, correction by peers and autocorrection [8, 3] are activities which modify the practices of teaching and learning related to writing. Today, still, correction is made in a traditional way because it consists of reading the copy and formulating written comments to students. These corrections serve to note the weak points and sometimes the key points of
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the work as well as to justify the mark obtained by the student [9]. Furthermore, teachers who carry out the same correction several times and a little bit mechanically tend to get stuck in automatic reactions, which, it is necessary to say, are sometimes necessary for his “survival” during intense periods of correction [10]. However, the correction generally leaves both the teacher and student dissatisfied [11]. Teachers complain about the arduousness of the task [12] and of the place occupied by evaluation in teaching [13]. Students complain about the difficulty in having to understand comments on the corrected copies and the extension of the correction [14, 6]. A part of the problem is that almost all of the teachers have never received training to correct [15, 12] because correction is traditionally associated with the teacher’s job. The evaluative act is an intuitive act in many ways [16] and many teachers still correct “instinctively”. This absence of training does not allow the understanding of the nature of the act of correcting [10, 17]. The Upper Council of Education [18] suggests looking for means to ensure initial correction training for collegial teachers and in-service training for teachers in practice.
Autocorrection and reflexive return The difference between autocorrection and reflexive return, in the correction of language, is mainly in the plan of the object of the correction that is to be made, and of the object of reflection [19]. If the reflexive return can be used for any learning, in an educational way, it demands good supervision from the professor. “We often speak about reflexive return as being the act by which the metacognition becomes concrete and thus that it is included by the learner. The reflection on its own work, its own manners to proceed and its own ideas allows the learner to become aware of its models and its schemas of thought. This awareness is important, because it favours the change and the growth necessary for the learning.” [20]. The correction is aimed mostly at the linguistic code, at the written language, and less often at the coherence, the fine and global logic of the structure of the text, and the sense of the text. Thanks to reflexive return, we can also make the students think about their global progress in French. According to Segreto [20], these are the main characteristics that reflexive return is aiming for: x It is a continual process that takes place in a natural way, following the realization of the works.
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x It carries on a particular theme, such as a particular work, or on skills in development. x It is global because we can ask the students to summarize their work or to give an overview. x It gradually gets the students accustomed to asking themselves significant questions. x By means of the examples given by the teacher and by peers, it settles down so that everyone uses a common vocabulary and builds strategies together [20].
3. Research questions We wanted to answer three research questions: • Which tools are used by students to improve their quality of French? • Do virtual tools improve the quality of French when compared to traditional tools? • Is the French quality of science students’ better than that of nonscience students’?
4. Methodology The sample was composed of 148 college students in biology, sociology or philosophy classes, aged between 16 and 19 years old. They had to write three essays: the first one by hand in the classroom; the second one at home with a computer and the tools of their choice; and the third one at home, with the obligation of using virtual tools to correct the language and of sending an electronic version to the teacher. These essays were corrected and annotated by their teacher. Students then had to do a recorrection (reflexive return) at home with the tools of their choice for the first essay, at home with a computer and the tools of their choice for the second essay, and in a computer laboratory with Antidote for the third one. Students were asked which tools they used for recorrection. Students in the science program were then compared with other students.
5. Results The sample (n=148) was mainly composed of girls (64.9 %). It was composed of students who are all registered in a pre-university program and who mainly speak French at home (73.0 %). The majority of the
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students have access to language correction software at home (56.8 %) and 38.5 % of the students use a laptop computer in class.
Use of correction tools The students in our sample use language correction software in their general training courses especially (66.2 %). They use them less for their specific training courses (47.3 %) and the least for their complementary training courses (28.4 %). Two thirds of the students said that they had used virtual language correction tools before their arrival at college. The vast majority of students (80.4 %) said that they often or always proceed to linguistic revision during the writing of a text. The girls (78.8 %) make linguistic revisions significantly more often than the boys (63.5 %) (t = 3.553, p =.001). In comparison, regarding the use of Antidote, which does not vary according to sex, the girls (80.2 %) use the proof-reader for Word significantly more often than the boys (60.9 %) during the correction of their school work (t = 4.013, p =.000). Students proceed to the correction of their school work whether they are long (93.3 %) or short (82.2 %). They also correct their letters (79.7 %) but less so their e-mails (51.4 %) and comments on social media (45.5 %), and they correct their texts messages the least (27.7 %). Table 1 shows that science students are considered less competent in using Antidote than those who are not in sciences (t=5.594, p